Abstract
The hepatitis C virus (HCV) encodes an RNA-dependent RNA polymerase (NS5B), which is indispensable for the viral genome replication. Although structural comparison among HCV NS5B, poliovirus 3D-pol, and human immunodeficiency virus-reverse transcriptase RNA-dependent polymerase reveals the canonical palm, fingers, and thumb domains, the crystal structure of HCV NS5B highlights the presence of a unique A1-loop, which extends from the fingers to the thumb domain (amino acids 12-46), providing many contact points for the proposed "closed" conformation of the enzyme. The polymerase also possesses a tunnel, which starts at the active site and terminates on the back surface of the enzyme. This tunnel of 19 A contains five basic amino acids, which may be engaged in NTP trafficking. In the present study, we exploited the crystal structure of the enzyme to elucidate the involvement of these two structural motifs in enzyme activity by site-directed mutagenesis. As predicted, the replacement of leucine 30 located in the Lambda 1-loop is detrimental to the NS5B activity. Heparin-Sepharose column chromatography and analytical ultracentrifugation experiments strongly suggest a local alteration in the structure of the Leu-30 mutant. An analysis of amino acid substitutions in Arg-222 and Lys-151 within the putative NTP tunnel indicates that Arg-222 was critical in delivering NTPs to the active site, whereas Lys-151 was dispensable. Interestingly, the substitution of lysine 151 for a glutamic acid resulted in an enzyme that was consistently more active in de novo synthesis as well as by "copy-back" mechanism of a self-primed substrate when compared with the wild type NS5B enzyme. Burst kinetic analyses indicate that the gain in function of K151E enzyme was primarily the result of the formation of more productive pre-initiation complexes that were used for the elongation reaction. In contrast to the recent observations, both the wild type and mutant enzymes were monomeric in solution, whereas molecules of higher order were apparent in the presence of RNA template.
Highlights
The hepatitis C virus (HCV) encodes an RNA-dependent RNA polymerase (NS5B), which is indispensable for the viral genome replication
Structural comparison among HCV NS5B, poliovirus 3D-pol, and human immunodeficiency virus-reverse transcriptase RNAdependent polymerase reveals the canonical palm, fingers, and thumb domains, the crystal structure of HCV NS5B highlights the presence of a unique A1-loop, which extends from the fingers to the thumb domain, providing many contact points for the proposed “closed” conformation of the enzyme
RNA replication by HCV NS5B has been reported by de novo synthesis [17,18,19], which has been reported for other viral polymerases including the bacteriophage 6, Q, the brome mosaic virus, and the bovine viral diarrhea virus (20 –25)
Summary
The hepatitis C virus (HCV) encodes an RNA-dependent RNA polymerase (NS5B), which is indispensable for the viral genome replication. Fingers and thumb domains as well as the putative NTP tunnel are well conserved among HCV NS5B, poliovirus 3D-pol, and human immunodeficiency virus-reverse transcriptase enzymes, the space between the fingers and the thumb domains of NS5B is unexpectedly small, giving rise to a proposed “closed” conformation, which has been identified for the double-stranded RNA polymerase of 6 [28]. Based on their crystal structures, both enzymes possess a loop that connects the fingers with the thumb. It is logical to hypothesize that the negatively charged incoming NTPs interact sequentially with positively charged amino acids to reach the active site within the NTP tunnel, systematic analysis of the nucleotide involvement in such trafficking has not been examined
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